Nuclear plant

ABSTRACT

This invention relates to a nuclear plant having a reactor vessel and a fluid circuit including flow path defining means, defining a flow path for circulating a reactor coolant fluid from and to the reactor vessel. The nuclear plant includes a particle collection zone defined along at least part of the length of the flow path, and particle deflection means arranged in particle deflecting relationship with the flow path to deflect particles from a fluid stream in the flow path into or toward the particle collection zone.

This application claims priority to PCT application PCT/IB2005/051572published as WO 2005/119698 in English on Dec. 15, 2005 and to SouthAfrican application 2004/3297 filed May 30, 2004, the entire contents ofeach are incorporated herein by reference.

BACKGROUND OF THE INVENTION

This invention relates to a nuclear plant. The invention extends to amethod of removing particles from a fluid stream.

SUMMARY OF INVENTION

According to one aspect of the invention, there is provided a nuclearplant having a reactor vessel and a fluid circuit including flow pathdefining means, defining a flow path for circulating a reactor coolantfluid from and to the reactor vessel, which nuclear plant includes aparticle collection zone defined along at least part of the length ofthe flow path; and particle deflection means arranged in particledeflecting relationship with the flow path to deflect particles from afluid stream in the flow path into or towards the particle collectionzone.

The nuclear plant may include particle ionisation means disposed in theflow path upstream of the particle deflection means for ionisingparticles in the fluid stream. The particle ionisation means may includeat least one ioniser selected from the group consisting of a neutronsource, a photon source, a heat source and an electromagnetic radiationsource, such as, for example, an X-ray emitter or a UV-emitter. It is tobe appreciated that the reactor vessel comprises, in use, a heat sourcefor ionisation of particles in the fluid stream.

In one embodiment of the invention, the particle collection zone isprovided by at least one particle deposition bed defined on an internalsurface of the flow path defining means.

At least part of a wall of the flow path defining means may then providethe/or each particle deposition bed. Instead, the/or each particledeposition bed may be provided by a deposition lining on the wall of theflow path defining means. The deposition bed may comprise a plurality oflayers of particle diffusion-resistant material.

At least one layer of the deposition bed may be comprised of a fluidmaterial. The nuclear plant may then include fluid material circulationmeans for circulating the fluid material such that fluid material can beremoved from and replaced to the deposition bed. The fluid circulationmeans may include secondary particle removal means for removingparticles collected in the fluid material therefrom, after removal ofthe fluid material from and prior to replacement of the fluid materialto the deposition bed.

In another embodiment of the invention, the particle collection zone isdefined by at least one magnetic trap, for trapping a charged particlein a magnetic field, provided on an internal surface of the flow pathdefining means. In this embodiment, a series of spaced magnetic trapsmay be provided at intervals on the internal surface of the flow pathdefining means.

More particularly, each magnetic trap may be defined as a peripherallyextending channel on the internal surface of the flow path definingmeans. The/or each recess may have a magnetic internal wall.

The particle deflection means may be provided by a magnetic deflectionarrangement, for generating a magnetic field in the flow path.

Preferably, the magnetic deflection arrangement generates a magneticfield of generally constant magnetic flux across a cross-sectional areatransverse to a direction of flow of the fluid stream.

To this end, the magnetic deflection arrangement may include at leasttwo pairs of opposed magnets arranged adjacent the flow path definingmeans, the magnets of a pair having inwardly disposed poles of oppositepolarity and the pairs being arranged so as to have angularly off-setpoles of like polarity. The poles of like polarity of the pairs ofopposed magnets may be angularly off-set by between about 0 degrees andabout 90 degrees, i.e. the angular orientation of a centreline of eachpair of opposed magnets may be varied relative to that of the at leastone other pair of magnets. Preferably, the poles of like polarity of thepairs of opposed magnets are off-set by about 45 degrees or about 90degrees.

Instead, or in addition, the magnetic deflection arrangement may includeat least one toroidal magnet arranged around the flow path definingmeans.

The magnets may be permanent magnets. Instead, the magnets may beelectromagnets.

According to another aspect of the invention, in a nuclear plant havinga reactor vessel and a fluid circuit including flow path defining means,defining a flow path for circulating a coolant fluid from and to thereactor vessel, there is provided a method of removing charged particlesfrom the coolant fluid, which method includes the steps of directing acoolant fluid stream containing charged particles along the flow path;applying a magnetic field across the flow path such that chargedparticles are deflected in the flow path; and collecting the deflectedcharged particles in a charged particle collection zone.

Collecting the charged particles will typically include retaining thecollected particles in the collection zone.

Applying the magnetic field across the flow path may include arrangingat least one permanent magnet in magnetic deflecting relationship withthe flow path. Instead, applying the magnetic field across the flow pathmay include arranging at least one electromagnet in magnetic deflectingrelationship with the flow path. Applying the magnetic field may theninclude pulsating the magnetic field.

Collecting the charged particles may include embedding the chargedparticles in a deposition material. The method may include, where thedeposition material is a fluid material, removing and replacing fluidmaterial in which particles have been collected. The method may includecirculating the fluid material through secondary particle removal meansto remove particles collected in the fluid material from the fluidmaterial.

Instead, collecting the charged particles may include providing anendless passage and channeling the deflected charged particles therein.

Channeling the particles in the endless passage may include applying amagnetic field across the endless passage.

According to still another aspect of the invention, there is provided aparticle deposition bed for the collection of particles, whichdeposition bed includes a body including one or more layers of at leastone particle diffusion-resistant material selected from the groupconsisting of graphite, chromium, platinum, a chromium alloy, mercury,liquid sodium, silicon carbide, SiN, SiFC and diamond.

Typically, the chromium alloy is a specialty chromium alloy havingparticle diffusion-resistant properties.

Preferably the body comprises a first layer of graphite, a second layerof a material selected from the group consisting of chromium, platinum,a chromium alloy, mercury and liquid sodium and a third layer of amaterial selected from the group consisting of silicon carbide, SiN,SiFC and diamond. The second layer may provide an intermediate layersandwiched between the first layer and the third layer.

In use, the first layer will typically provide an operatively innerlayer and the third layer will typically provide an operatively outerlayer.

The deposition bed may be provided on a base element on an operativelyinner surface of said base element. Said base element may be tubularcircular cylindrical and may be configured to provide part of a wall offlow path defining means, which forms part of a fluid circuit. The baseelement may be removably inserted into the fluid circuit to form part ofthe flow path defining means such that it can be removed, forreplacement by a like base element having a fresh deposition bed, uponsaturation of at least part of the deposition bed withembedded/collected particles.

According to yet another aspect of the invention, there is provided amagnetic trap arrangement for trapping charged particles, which traparrangement includes a flow passage defining element defining a flowpassage, for providing part of a flow path of a fluid circuit, andhaving at least one peripherally extending channel provided on aninternal surface thereof, the at least one channel having a magneticinternal wall.

A series of longitudinally spaced peripherally extending channels may beprovided on the internal surface of the flow passage defining element.

The flow passage defining element may be tubular circular cylindrical.

According to a further aspect of the invention, there is provided amethod of removing particles from a fluid stream, which method includesthe steps of deflecting particles from a fluid stream towards a particledeposition bed including at least one layer of fluid depositionmaterial; collecting particles in the fluid deposition material; andremoving and replacing the fluid deposition material of the particledeposition bed.

Preferably, the method includes circulating the fluid depositionmaterial through secondary particle removal means for removing particlescollected in the fluid deposition material from the fluid depositionmaterial.

More particularly, the method may include circulating the fluiddeposition material along a fluid material flow path through secondaryparticle removal means, including a particle collection zone, definedalong the length of the fluid material flow path, and particledeflection means, arranged in particle deflecting relationship with thefluid material flow path, for deflecting particles from the fluidmaterial into the particle collection zone.

Instead, or in addition, the method may include circulating the fluiddeposition material along a fluid material flow path through secondaryparticle removal means, provided by a biofilter, for removing particlesfrom the fluid deposition material by use of living organisms, typicallybacteria.

The fluid deposition material may be provided by mercury or liquidsodium.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a schematic view of a plant of a nuclear plant inaccordance with the invention.

FIG. 2 shows a three-dimensional view of part of a fluid circuit of anuclear plant in accordance with the invention.

FIG. 3 shows a three-dimensional view of part of another fluid circuitof a nuclear plant in accordance with the invention.

FIG. 4 shows a longitudinal sectional view of part of the fluid circuitof a nuclear plant in accordance with the invention.

FIG. 5 shows a longitudinal sectional view of part of another fluidcircuit of a nuclear plant in accordance with the invention.

FIG. 6 shows a schematic view of a magnetic field applied across thepart of a fluid circuit of FIG. 3 in three-dimensional longitudinalsection.

FIG. 7 shows a schematic view of a coercive force field applied acrossthe part of a fluid circuit of FIG. 3 in three-dimensional longitudinalsection.

FIG. 8 shows a three-dimensional view of charged particle deflections inthe part of a fluid circuit of FIG. 3.

FIG. 9 shows an end view of the charged particle deflections of FIG. 8.

FIG. 10 shows a side view of the charged particle deflections of FIG. 8.

DESCRIPTION

The invention will now be described, by way of example, with referenceto the accompanying diagrammatic drawings.

In FIG. 1 of the drawings, reference numeral 10 refers generally to partof a nuclear plant. The nuclear plant 10 includes a reactor vessel 12and a fluid circuit, generally indicated by reference numeral 14,including flow path defining means 16, defining a flow path forcirculating a reactor coolant fluid from and to the reactor vessel 12.Naturally, the plant 10 will include other components such as coolantfluid circulation means for circulating coolant fluid to and from thereactor vessel. However, details of these components are not requiredfor an understanding of the invention and they are accordingly not shownin the drawings.

Reference is now made to FIGS. 2 and 3 of the drawings, each of whichdepicts part of the fluid circuit 14 of FIG. 1 and, unless otherwiseindicated, the same reference numerals used above are used to designatesimilar parts.

The flow path defining means 16 includes an inner circular cylindricalpipe 18, defining a flow path 19, and an outer circular cylindrical pipe20, concentric and coaxial with the inner pipe 18. An annular cavity 22is defined between the inner pipe 18 and the outer pipe 20 and a thermalinsulating material 24 is interposed between the inner and outer pipes18, 20 in the annular cavity 22.

An outermost tubular cylindrical pressure boundary wall 26 is arrangedaround the inner and outer pipes 18, 20, to be concentric and coaxialtherewith.

Hot coolant gas from the reactor vessel 12 is conveyed, in use, in thedirection of the arrow 28 (or in an opposite direction to the arrow 28)through the coolant fluid circuit 14 to drive a power turbine or steamgenerator or other power conversion device (not shown) and is cooled andcompressed prior to being returned to the reactor vessel 12 via thefluid circuit 14. The hot coolant gas emanating from the reactor vessel12 typically contains contaminants including, for example, ionisedisotopes and radioisotopes, as well as other ions.

The nuclear plant 10 includes a magnetic deflection arrangement 30 forapplying a magnetic field across the flow path 19 and generating amagnetic field in the flow path 19. The magnetic deflection arrangement30 includes magnets arranged between the pressure boundary wall 26 andthe outer pipe 20 at positions along the length of the flow path 19. Inthe embodiments of FIGS. 2 and 3 of the drawings, the magnets arepermanent magnets (of a ceramic material incorporating rare earthmetal(s)). It is to be appreciated, however, that the magnets mayinstead be electromagnets.

In one embodiment, the nuclear plant 10 includes particle ionisationmeans 31 (FIG. 1), including an ioniser such as a neutron orelectromagnetic radiation source e.g. X-ray or UV emitter, disposed inthe flow path 19 upstream of the magnetic deflection arrangement 30,i.e. between an outlet of the reactor vessel 12 and the magneticdeflection arrangement 30. The ionisation means 31 increases the numberof charged particles in the fluid stream at the position along thelength of the flow path 19 at which the magnetic deflection arrangement30 is provided, by ionisation of the particles conveyed in the fluidstream prior to their conveyance through that part of the flow pathdefining means 16 at which the magnetic deflection arrangement 30 isprovided.

In FIG. 2, the magnetic deflection arrangement 30 includes three pairs32, 34, 36 of ring segment magnets 38 arranged adjacent to an outer wall39 of the outer pipe 20 at longitudinally spaced positions. The magnets38 of each pair 32, 34, 36 are located at diametrically positions andare arranged such that poles 40 of opposite polarity of the magnets 38of any pair 32, 34, 36 face inwardly and outwardly, respectively. Inthis way, each pair of magnets 32, 34, 36 comprises a magnet 38 havingan outwardly-directed north pole and an inwardly-directed south pole,and an opposed magnet 38 having an outwardly-directed south pole and aninwardly directed north pole.

The poles 40 of the magnets 38 of each pair 32, 34, 36 are angularlyoff-set from the poles 40 of the magnets 38 of each other pair 32, 34,36. Preferably, as shown in FIG. 2, the poles 40 of the magnets 38 ofthe pairs 32 and 34, and 34 and 36, respectively, are off-set by about45 degrees. Hence, the poles 40 of the magnets 38 of the pair 36 areoff-set by about 90 degrees relative to those in the pair 32. TheInventors are of the view that magnetic fields of approximately constantmagnetic flux will be obtained over the cross-section of the pipe 18 ateach pair 32, 34, 36 of opposing magnets. Naturally, the poles 40 of themagnets 38 of the pairs 32, 34, 36 may be angularly off-set by othermagnitudes of angle.

Reference is now made to FIG. 3 of the drawings, in which the magneticdeflection arrangement 30 includes a toroidal magnet 41 arranged aroundthe outer pipe 20. The magnetic deflection arrangement further includestwo pairs 42, 44 of magnets 38, similar to the pairs of magnets 32, 34,36 of FIG. 2, the pairs 42, 44 and magnet 40 being longitudinally spacedalong the outer pipe 20, between the pressure boundary wall 26 and theouter pipe 20.

The magnetic deflection arrangement 30 generates a magnetic field in theflow path 19 such that a particle having a charge, such as an ion in thecoolant fluid stream, and moving with a velocity through the magneticfield will experience a force (a Lorentz force) and be deflected fromits path of travel towards an internal surface of the inner pipe 18.

FIG. 4 of the drawings shows part of the flow path defining means 16 ofthe fluid circuit 14 in longitudinal cross-section and, unless otherwiseindicated, the same reference numerals used above are used to designatesimilar parts. An internal surface of the inner pipe 18, defining theflow path 19, has a deposition lining 50 provided thereon. Thedeposition lining 50 defines a particle deposition bed 52 which providesa collection zone into which charged particles, e.g. ionised isotopes,can be deflected and embedded (ie. collected and retained) thereby to beremoved from the coolant fluid stream.

The deposition lining 50 comprises a plurality of layers of materials,which resist particle diffusion therethrough. In a preferred embodiment,the lining 50 includes a radially innermost layer 54 of graphite,defining a charged particle landing zone and providing a decelerator forthe charged particles. The layer 54 may, however, instead be comprisedof any other suitable soft temperature-resistant material. Anintermediate layer 56 of chromium is sandwiched between the graphitelayer 54 and an outer layer 58 of silicon carbide. The chromium layer 56provides a trap for silver atoms/ions, which exhibit an affinity forchromium. Instead of chromium, platinum or an alloy resistant toradiation damage, such as a Specialty Chromium Alloy, may be used. Thematerial of the layer 56 typically attracts captured charged particlesthrough the layer 54 of graphite, or other soft material, into the layer56. The silicon carbide provides an outer barrier layer 58 forinhibiting diffusion of ionised isotopes and other ions through the wallof the inner pipe 18. Instead of silicon carbide, the outer layer 58 maybe comprised of SiN, SiFC or diamond.

That part of the inner pipe 18 having the deposition lining 50 providedthereon (illustrated in FIG. 4) may be comprised by a tubular circularcylindrical base element providing a pipe segment, which is removablyinserted into the fluid circuit 14 to form part of the flow pathdefining means 16. The pipe segment/base element may thus be removedduring shutdown or reactor maintenance, typically when the depositionlining 50 is saturated with embedded charged particles, and replacedwith another like pipe segment/base element having a fresh depositionlining 50 for particle collection. Saturation of the deposition lining50 may be determined, for example, on a pre-calculated fixed term basis(i.e. after expiration of a predetermined number of hours of reactoroperation) or by active measurement of a saturation level of thedeposition lining 50. The removed pipe segment/base element willtypically be stored on a long term basis.

In another embodiment of the invention, the intermediate layer 56 is ofa fluid material, such as, for example, mercury or liquid sodium. Thenuclear plant 10 then typically will include means (not shown) forremoving the fluid material of the layer 56 from the deposition lining50 and providing substitute fluid material therefor or returning thefluid material to the deposition lining 50. Where the fluid material isremoved from the deposition lining 50 to be returned thereto, thenuclear plant 10 will typically include fluid material circulation means(not shown), defining a fluid material flow path, for circulating thefluid material, via secondary particle removal means (not shown), fromand to the deposition lining 50. The secondary particle removal meanswill serve to remove particles collected in the fluid material of thelayer 56 from the fluid material during circulation thereof, so thatfluid material returned to the deposition lining 50 is purged ofparticle contaminants. The Applicant believes that this will result inan increased lifetime of the deposition lining 50 and reduce the needfor shutdown or maintenance of the nuclear plant 10 in order to replacethe deposition lining 50 due to saturation with embedded particles. Thesecondary particle removal means may be provided, for example, by aparticle collection zone, defined along the length of the fluid materialflow path, and particle deflection means (typically a magnetarrangement) arranged in particle deflecting relationship with the fluidmaterial flow path to deflect particles from the fluid material into theparticle collection zone. Instead, the secondary particle removal meansmay be provided by a biofilter, for removing particles from the fluiddeposition material by use of living organisms, typically bacteria,which, for example, may consume the contaminant particles.

In the embodiment of the invention shown in FIG. 5 of the drawings, inwhich the same reference numerals used above designate similar parts, acharged particle collection zone is defined by a series oflongitudinally spaced magnetic traps 60, provided on an internal surfaceof the flow path defining means 16. Here, the inner pipe 18 is omittedfrom that part of the fluid circuit 14 in which the particle collectionzone is provided. In the embodiment shown, each magnetic trap 60 isprovided by a channel-section ring formation 62, having magneticinternal walls 64. The ring formations 62 are arranged in side-by-sidelongitudinally spaced relationship against an internal surface 66 of theouter pipe 20 so as to extend circumferentially around the outer pipe 20and define longitudinally spaced peripheral channels 68, each providingan endless passage, along the flow path defining means 16. The channels68 are lipped. A magnetic field is generated within each channel 68 bythe magnetic internal walls 64 thereof such that a charged particledeflected into a channel 68, by the magnetic field applied across theflow path 19, will be displaced along the endless passage under theinfluence of the magnetic field of the channel 68 and will thereby betrapped in the relevant channel 38.

The flow path defining means will typically have an internal diameter ofbetween about 1 metre and about 1.5 metres. Typically, the depositionbed 52, or, alternatively, the arrangement of channels 68, will extendfor a length of between about 2 times to about 5 times the internaldiameter, i.e. in the present embodiment extending for about 4 metres,along the length of the flow path defining means, and will be positionedas close as possible to an outlet from the reactor vessel 12.

In use, coolant fluid leaving the reactor vessel 12 is fed through thefluid circuit 16 along the flow path 19. The magnetic field arising fromthe magnetic deflection arrangement 30 interacts with the chargedparticle products, of nuclear fission reactions in the reactor vessel,which are contained in the coolant fluid stream and the particles aredeflected radially outwardly thereby, in the direction of coolant fluidflow 28, toward the internal surface of the flow path defining means 16.FIGS. 6 and 7 of the drawings illustrate the magnetic field and thecoercive force field, respectively, for the magnetic deflectionarrangement 30 of FIG. 3 of the drawings. FIGS. 8 to 10 illustrate thepaths of travel of deflected charged particles in the coolant fluidstream. FIGS. 8 to 10 are for illustrative purposes only, the particlesfor which deflection pathways are illustrated being simulated particleshaving masses greater than the atomic masses of known existing elements.It will be appreciated that the magnitude of the force experienced byany particular charged particle, and hence its degree of deflection,will be dependant on the velocity with which the particle moves throughthe magnetic field applied across the flow path 19 as well as particleproperties, such as the particle's mass, charge/degree of ionisation andmagnetic moment.

In the embodiment of FIG. 4 of the drawings, the particles deflectedtoward the internal surface of the inner pipe 18 are propelled into thedeposition lining 50. The particles land on the inner graphite layer 54where they are decelerated. Some particles are embedded within thegraphite layer 54, whilst others pass through the layer 54 into theunderlying layer 56 of chromium. In particular, silver ions have anaffinity for the chromium layer 56. Those particles, which diffusethrough the intermediate chromium layer 56, are finally embedded in theouter silicon carbide layer 58 and diffusion of the charged particlesthrough the inner pipe 18 is thus inhibited. The ionised isotopes andother ions are collected and retained in the particle deposition bed 52comprised by the deposition lining 50 so that the coolant fluiddownstream of the deposition bed 52 is purged of these ion or isotopecontaminants. In another embodiment of the invention (not shown), thewall of the flow path defining means is of a particlediffusion-resistant material and provides the deposition bed without aninternal deposition lining being provided.

In the embodiment of FIG. 5 of the drawings, a deflected chargedparticle is propelled into one of the series of longitudinally spacedmagnetic traps 60 on an internal surface of the flow path defining means16. Here the particle is displaced in a spiral motion along the endlesspassage provided by the channel 68, under the influence of the magneticfield generated within the channel 68 by the magnetic internal walls 64thereof. The fluid stream is thus similarly purged of ionised isotopesand other charged particle contaminants.

The Applicant believes that the nuclear plant 10 and method of theinvention will provide an effective means of removing harmfulradioactive contaminants from a coolant fluid of a nuclear power plant.This in turn, it is believed, will render maintenance of the fluidcircuit components downstream of the particle collection zone/particledeposition bed 52/magnetic trap arrangement 60 in the nuclear plant 10 asafer activity. In particular, in a nuclear plant having a single fluidcircuit in which the reactor vessel and power conversion unit arearranged in series, and which operates on a closed direct Brayton cycle,where working/coolant fluid from the reactor vessel passes through thepower conversion unit, it is believed that the method/apparatus of theinvention will alleviate build-up of particles in the power conversionunit and other downstream components and reduce the need for maintenancethereof. Where the magnetic deflecting arrangement 30 includeselectromagnets, it is believed that pulsating the magnetic field willimprove the efficiency of removing the charged particles from thecoolant fluid. Further, it is believed that by providing angularlyoff-set pairs of magnets in the magnetic deflecting arrangement 30, thecharged particle removal efficiency is improved.

While embodiments of the invention have been illustrated and described,it is not intended that these embodiments illustrate and describe allpossible forms of the invention. Rather, the words used in thespecification are words of description rather than limitation, and it isunderstood that various changes may be made without departing from thespirit and scope of the invention.

1. A nuclear plant including a reactor vessel, a fluid circuit whichincludes flow path defining means defining a flow path for circulating areactor coolant fluid from and to the reactor vessel, a particlecollection zone defined along at least part of the length of the flowpath, and particle deflection means arranged in particle deflectingrelationship with the flow path to deflect charged particles from areactor coolant fluid stream in the flow path into or towards theparticle collection zone, characterized in that (i) the particledeflection means is provided by a magnetic deflection arrangement forgenerating a magnetic field in the flow path; and (ii) the particlecollection zone comprises a deposition material in which the deflectedcharged particles can be embedded.
 2. A nuclear plant as claimed inclaim 1, which includes particle ionisation means disposed in the flowpath upstream of the particle deflection means for ionising particles inthe fluid stream.
 3. A nuclear plant as claimed in claim 2, in which theparticle ionisation means includes at least one ioniser selected fromthe group consisting of a neutron source, photon source, heat source andan electromagnetic radiation source.
 4. A nuclear plant as claimed inclaim 1, in which the magnetic deflection arrangement is adapted togenerate a magnetic field of generally constant magnetic flux across across-sectional area transverse to a direction of flow of the fluidstream.
 5. A nuclear plant as claimed in claim 1, in which the magneticdeflection arrangement includes at least two pairs of opposed magnetsarranged adjacent the flow path defining means, the magnets of a pairhaving inwardly disposed poles of opposite polarity and the pairs beingarranged so as to have angularly off-set poles of like polarity.
 6. Anuclear plant as claimed in claim 5, in which the poles of like polarityof the pairs of opposed magnets are angularly off-set by between 0degrees and 90 degrees.
 7. A nuclear plant as claimed in claim 6, inwhich the poles of like polarity of the pairs of opposed magnets areoff-set by 45 degrees.
 8. A nuclear plant as claimed in claim 6, inwhich the poles of like polarity of the pairs of opposed magnets areoff-set by 90 degrees.
 9. A nuclear plant as claimed in claim 1, inwhich the magnetic deflection arrangement includes at least one toroidalmagnet arranged around the flow path defining means.
 10. A nuclear plantas claimed in claim 1, in which the magnetic deflection arrangementincludes at least one permanent magnet.
 11. A nuclear plant as claimedin claim 1, in which the magnetic deflection arrangement includes atleast one electromagnet.
 12. A nuclear plant as claimed in claim 1, inwhich the deposition material forms part of at least one particledeposition bed defined on an internal surface of the flow path definingmeans.
 13. A nuclear plant as claimed in claim 12, in which at leastpart of a wall of the flow path defining means provides the at least oneparticle deposition bed.
 14. A nuclear plant as claimed in claim 12, inwhich the at least one particle deposition bed is provided by adeposition lining on an internal surface of the flow path definingmeans.
 15. A nuclear plant as claimed in claim 12, in which thedeposition bed comprises a plurality of layers of particlediffusion-resistant material.
 16. A nuclear plant as claimed in claim15, in which at least one layer of the deposition bed is comprised of afluid material.
 17. A nuclear plant as claimed in claim 16, whichincludes fluid material circulation means for circulating the fluidmaterial such that fluid material can be removed from and replaced tothe deposition bed.
 18. A nuclear plant as claimed in claim 17, in whichthe fluid circulation means includes secondary particle removal meansfor removing particles collected in the fluid material therefrom, afterremoval of the fluid material from and prior to replacement of the fluidmaterial to the deposition bed.
 19. A method of removing chargedparticles from a coolant fluid in a nuclear plant having a reactorvessel and a fluid circuit which includes flow path defining meansdefining a flow path for circulating the coolant fluid from and to thereactor vessel, the method including: directing a stream of the coolantfluid and which contains charged particles along the flow path; applyinga magnetic field across the flow path such that charged particles aredeflected in the flow path; and embedding the deflected chargedparticles in a deposition material.
 20. A method as claimed in claim 19,wherein the deposition material forms part of at least one particledeposition bed defined on an internal surface of the flow path definingmeans.
 21. A method as claimed in claim 20, wherein the deposition bedcomprises a plurality of layers of particle diffusion-resistantmaterial.
 22. A method as claimed in claim 19, which includes, where thedeposition material is a fluid material, removing and replacing fluidmaterial in which particles have been collected.
 23. A method as claimedin claim 22, which includes circulating the fluid material throughsecondary particle removal means to remove particles collected in thefluid material from the fluid material.
 24. A method as claimed in claim19, in which applying the magnetic field across the flow path includesarranging at least one permanent magnet in magnetic deflectingrelationship with the flow path.
 25. A method as claimed in claim 19,wherein a magnetic field of generally constant magnetic flux across across-sectional area transverse to a direction of flow of fluid stream,is generated.
 26. A method as claimed in claim 19, in which applying themagnetic field across the flow path includes arranging at least oneelectromagnet in magnetic deflecting relationship with the flow path.27. A method as claimed in claim 26, in which applying the magneticfield includes pulsating the magnetic field.